/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2024 The FreeBSD Foundation * * This software was developed by Konstantin Belousov * under sponsorship from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "opt_acpi.h" #include "opt_ddb.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pcib_if.h" #include #include #include #include #include #include #include #include #include static int amdiommu_enable = 0; /* * All enumerated AMD IOMMU units. * Access is unlocked, the list is not modified after early * single-threaded startup. */ static TAILQ_HEAD(, amdiommu_unit) amdiommu_units = TAILQ_HEAD_INITIALIZER(amdiommu_units); typedef bool (*amdiommu_itercc_t)(void *, void *); typedef bool (*amdiommu_iter40_t)(ACPI_IVRS_HARDWARE2 *, void *); typedef bool (*amdiommu_iter11_t)(ACPI_IVRS_HARDWARE2 *, void *); typedef bool (*amdiommu_iter10_t)(ACPI_IVRS_HARDWARE1 *, void *); static bool amdiommu_ivrs_iterate_tbl_typed(amdiommu_itercc_t iter, void *arg, int type, ACPI_TABLE_IVRS *ivrs_tbl) { char *ptr, *ptrend; bool done; done = false; ptr = (char *)ivrs_tbl + sizeof(*ivrs_tbl); ptrend = (char *)ivrs_tbl + ivrs_tbl->Header.Length; for (;;) { ACPI_IVRS_HEADER *ivrsh; if (ptr >= ptrend) break; ivrsh = (ACPI_IVRS_HEADER *)ptr; if (ivrsh->Length <= 0) { printf("amdiommu_iterate_tbl: corrupted IVRS table, " "length %d\n", ivrsh->Length); break; } ptr += ivrsh->Length; if (ivrsh->Type == type) { done = iter((void *)ivrsh, arg); if (done) break; } } return (done); } /* * Walk over IVRS, calling callback iterators following priority: * 0x40, then 0x11, then 0x10 subtable. First iterator returning true * ends the walk. * Returns true if any iterator returned true, otherwise false. */ static bool amdiommu_ivrs_iterate_tbl(amdiommu_iter40_t iter40, amdiommu_iter11_t iter11, amdiommu_iter10_t iter10, void *arg) { ACPI_TABLE_IVRS *ivrs_tbl; ACPI_STATUS status; bool done; status = AcpiGetTable(ACPI_SIG_IVRS, 1, (ACPI_TABLE_HEADER **)&ivrs_tbl); if (ACPI_FAILURE(status)) return (false); done = false; if (iter40 != NULL) done = amdiommu_ivrs_iterate_tbl_typed( (amdiommu_itercc_t)iter40, arg, ACPI_IVRS_TYPE_HARDWARE3, ivrs_tbl); if (!done && iter11 != NULL) done = amdiommu_ivrs_iterate_tbl_typed( (amdiommu_itercc_t)iter11, arg, ACPI_IVRS_TYPE_HARDWARE2, ivrs_tbl); if (!done && iter10 != NULL) done = amdiommu_ivrs_iterate_tbl_typed( (amdiommu_itercc_t)iter10, arg, ACPI_IVRS_TYPE_HARDWARE1, ivrs_tbl); AcpiPutTable((ACPI_TABLE_HEADER *)ivrs_tbl); return (done); } struct ivhd_lookup_data { struct amdiommu_unit *sc; uint16_t devid; }; static bool ivrs_lookup_ivhd_0x40(ACPI_IVRS_HARDWARE2 *h2, void *arg) { struct ivhd_lookup_data *ildp; KASSERT(h2->Header.Type == ACPI_IVRS_TYPE_HARDWARE2 || h2->Header.Type == ACPI_IVRS_TYPE_HARDWARE3, ("Misparsed IVHD, h2 type %#x", h2->Header.Type)); ildp = arg; if (h2->Header.DeviceId != ildp->devid) return (false); ildp->sc->unit_dom = h2->PciSegmentGroup; ildp->sc->efr = h2->EfrRegisterImage; return (true); } static bool ivrs_lookup_ivhd_0x10(ACPI_IVRS_HARDWARE1 *h1, void *arg) { struct ivhd_lookup_data *ildp; KASSERT(h1->Header.Type == ACPI_IVRS_TYPE_HARDWARE1, ("Misparsed IVHD, h1 type %#x", h1->Header.Type)); ildp = arg; if (h1->Header.DeviceId != ildp->devid) return (false); ildp->sc->unit_dom = h1->PciSegmentGroup; return (true); } static u_int amdiommu_devtbl_sz(struct amdiommu_unit *sc __unused) { return (sizeof(struct amdiommu_dte) * (1 << 16)); } static void amdiommu_free_dev_tbl(struct amdiommu_unit *sc) { u_int devtbl_sz; devtbl_sz = amdiommu_devtbl_sz(sc); pmap_qremove((vm_offset_t)sc->dev_tbl, atop(devtbl_sz)); kva_free((vm_offset_t)sc->dev_tbl, devtbl_sz); sc->dev_tbl = NULL; vm_object_deallocate(sc->devtbl_obj); sc->devtbl_obj = NULL; } static int amdiommu_create_dev_tbl(struct amdiommu_unit *sc) { vm_offset_t seg_vaddr; u_int devtbl_sz, dom, i, reclaimno, segnum_log, segnum, seg_sz; int error; static const int devtab_base_regs[] = { AMDIOMMU_DEVTAB_BASE, AMDIOMMU_DEVTAB_S1_BASE, AMDIOMMU_DEVTAB_S2_BASE, AMDIOMMU_DEVTAB_S3_BASE, AMDIOMMU_DEVTAB_S4_BASE, AMDIOMMU_DEVTAB_S5_BASE, AMDIOMMU_DEVTAB_S6_BASE, AMDIOMMU_DEVTAB_S7_BASE }; segnum_log = (sc->efr & AMDIOMMU_EFR_DEVTBLSEG_MASK) >> AMDIOMMU_EFR_DEVTBLSEG_SHIFT; segnum = 1 << segnum_log; KASSERT(segnum <= nitems(devtab_base_regs), ("%s: unsupported devtab segment count %u", __func__, segnum)); devtbl_sz = amdiommu_devtbl_sz(sc); seg_sz = devtbl_sz / segnum; sc->devtbl_obj = vm_pager_allocate(OBJT_PHYS, NULL, atop(devtbl_sz), VM_PROT_ALL, 0, NULL); if (bus_get_domain(sc->iommu.dev, &dom) == 0) sc->devtbl_obj->domain.dr_policy = DOMAINSET_PREF(dom); sc->hw_ctrl &= ~AMDIOMMU_CTRL_DEVTABSEG_MASK; sc->hw_ctrl |= (uint64_t)segnum_log << ilog2(AMDIOMMU_CTRL_DEVTABSEG_2); sc->hw_ctrl |= AMDIOMMU_CTRL_COHERENT; amdiommu_write8(sc, AMDIOMMU_CTRL, sc->hw_ctrl); seg_vaddr = kva_alloc(devtbl_sz); if (seg_vaddr == 0) return (ENOMEM); sc->dev_tbl = (void *)seg_vaddr; for (i = 0; i < segnum; i++) { vm_page_t m; uint64_t rval; for (reclaimno = 0; reclaimno < 3; reclaimno++) { VM_OBJECT_WLOCK(sc->devtbl_obj); m = vm_page_alloc_contig(sc->devtbl_obj, i * atop(seg_sz), VM_ALLOC_NORMAL | VM_ALLOC_NOBUSY, atop(seg_sz), 0, ~0ul, IOMMU_PAGE_SIZE, 0, VM_MEMATTR_DEFAULT); VM_OBJECT_WUNLOCK(sc->devtbl_obj); if (m != NULL) break; error = vm_page_reclaim_contig(VM_ALLOC_NORMAL, atop(seg_sz), 0, ~0ul, IOMMU_PAGE_SIZE, 0); if (error != 0) vm_wait(sc->devtbl_obj); } if (m == NULL) { amdiommu_free_dev_tbl(sc); return (ENOMEM); } rval = VM_PAGE_TO_PHYS(m) | (atop(seg_sz) - 1); for (u_int j = 0; j < atop(seg_sz); j++, seg_vaddr += PAGE_SIZE, m++) { pmap_zero_page(m); pmap_qenter(seg_vaddr, &m, 1); } amdiommu_write8(sc, devtab_base_regs[i], rval); } return (0); } static int amdiommu_cmd_event_intr(void *arg) { struct amdiommu_unit *unit; uint64_t status; unit = arg; status = amdiommu_read8(unit, AMDIOMMU_CMDEV_STATUS); if ((status & AMDIOMMU_CMDEVS_COMWAITINT) != 0) { amdiommu_write8(unit, AMDIOMMU_CMDEV_STATUS, AMDIOMMU_CMDEVS_COMWAITINT); taskqueue_enqueue(unit->x86c.qi_taskqueue, &unit->x86c.qi_task); } if ((status & (AMDIOMMU_CMDEVS_EVLOGINT | AMDIOMMU_CMDEVS_EVOVRFLW)) != 0) amdiommu_event_intr(unit, status); return (FILTER_HANDLED); } static int amdiommu_setup_intr(struct amdiommu_unit *sc) { int error, msi_count, msix_count; msi_count = pci_msi_count(sc->iommu.dev); msix_count = pci_msix_count(sc->iommu.dev); if (msi_count == 0 && msix_count == 0) { device_printf(sc->iommu.dev, "needs MSI-class intr\n"); return (ENXIO); } #if 0 /* * XXXKIB how MSI-X is supposed to be organized for BAR-less * function? Practically available hardware implements only * one IOMMU unit per function, and uses MSI. */ if (msix_count > 0) { sc->msix_table = bus_alloc_resource_any(sc->iommu.dev, SYS_RES_MEMORY, &sc->msix_tab_rid, RF_ACTIVE); if (sc->msix_table == NULL) return (ENXIO); if (sc->msix_pba_rid != sc->msix_tab_rid) { /* Separate BAR for PBA */ sc->msix_pba = bus_alloc_resource_any(sc->iommu.dev, SYS_RES_MEMORY, &sc->msix_pba_rid, RF_ACTIVE); if (sc->msix_pba == NULL) { bus_release_resource(sc->iommu.dev, SYS_RES_MEMORY, &sc->msix_tab_rid, sc->msix_table); return (ENXIO); } } } #endif error = ENXIO; if (msix_count > 0) { error = pci_alloc_msix(sc->iommu.dev, &msix_count); if (error == 0) sc->numirqs = msix_count; } if (error != 0 && msi_count > 0) { error = pci_alloc_msi(sc->iommu.dev, &msi_count); if (error == 0) sc->numirqs = msi_count; } if (error != 0) { device_printf(sc->iommu.dev, "Failed to allocate MSI/MSI-x (%d)\n", error); return (ENXIO); } /* * XXXKIB Spec states that MISC0.MsiNum must be zero for IOMMU * using MSI interrupts. But at least one BIOS programmed '2' * there, making driver use wrong rid and causing * command/event interrupt ignored as stray. Try to fix it * with dirty force by assuming MsiNum is zero for MSI. */ sc->irq_cmdev_rid = 1; if (msix_count > 0) { sc->irq_cmdev_rid += pci_read_config(sc->iommu.dev, sc->seccap_reg + PCIR_AMDIOMMU_MISC0, 4) & PCIM_AMDIOMMU_MISC0_MSINUM_MASK; } sc->irq_cmdev = bus_alloc_resource_any(sc->iommu.dev, SYS_RES_IRQ, &sc->irq_cmdev_rid, RF_SHAREABLE | RF_ACTIVE); if (sc->irq_cmdev == NULL) { device_printf(sc->iommu.dev, "unable to map CMD/EV interrupt\n"); return (ENXIO); } error = bus_setup_intr(sc->iommu.dev, sc->irq_cmdev, INTR_TYPE_MISC, amdiommu_cmd_event_intr, NULL, sc, &sc->irq_cmdev_cookie); if (error != 0) { device_printf(sc->iommu.dev, "unable to setup interrupt (%d)\n", error); return (ENXIO); } bus_describe_intr(sc->iommu.dev, sc->irq_cmdev, sc->irq_cmdev_cookie, "cmdev"); if (x2apic_mode) { AMDIOMMU_LOCK(sc); sc->hw_ctrl |= AMDIOMMU_CTRL_GA_EN | AMDIOMMU_CTRL_XT_EN; amdiommu_write8(sc, AMDIOMMU_CTRL, sc->hw_ctrl); // XXXKIB AMDIOMMU_CTRL_INTCAPXT_EN and program x2APIC_CTRL AMDIOMMU_UNLOCK(sc); } return (0); } static int amdiommu_probe(device_t dev) { int seccap_reg; int error; uint32_t cap_h, cap_type, cap_rev; if (acpi_disabled("amdiommu")) return (ENXIO); TUNABLE_INT_FETCH("hw.amdiommu.enable", &amdiommu_enable); if (!amdiommu_enable) return (ENXIO); if (pci_get_class(dev) != PCIC_BASEPERIPH || pci_get_subclass(dev) != PCIS_BASEPERIPH_IOMMU) return (ENXIO); error = pci_find_cap(dev, PCIY_SECDEV, &seccap_reg); if (error != 0 || seccap_reg == 0) return (ENXIO); cap_h = pci_read_config(dev, seccap_reg + PCIR_AMDIOMMU_CAP_HEADER, 4); cap_type = cap_h & PCIM_AMDIOMMU_CAP_TYPE_MASK; cap_rev = cap_h & PCIM_AMDIOMMU_CAP_REV_MASK; if (cap_type != PCIM_AMDIOMMU_CAP_TYPE_VAL && cap_rev != PCIM_AMDIOMMU_CAP_REV_VAL) return (ENXIO); device_set_desc(dev, "DMA remap"); return (BUS_PROBE_SPECIFIC); } static int amdiommu_attach(device_t dev) { struct amdiommu_unit *sc; struct ivhd_lookup_data ild; int error; uint32_t base_low, base_high; bool res; sc = device_get_softc(dev); sc->iommu.unit = device_get_unit(dev); sc->iommu.dev = dev; error = pci_find_cap(dev, PCIY_SECDEV, &sc->seccap_reg); if (error != 0 || sc->seccap_reg == 0) return (ENXIO); base_low = pci_read_config(dev, sc->seccap_reg + PCIR_AMDIOMMU_BASE_LOW, 4); base_high = pci_read_config(dev, sc->seccap_reg + PCIR_AMDIOMMU_BASE_HIGH, 4); sc->mmio_base = (base_low & PCIM_AMDIOMMU_BASE_LOW_ADDRM) | ((uint64_t)base_high << 32); sc->device_id = pci_get_rid(dev); ild.sc = sc; ild.devid = sc->device_id; res = amdiommu_ivrs_iterate_tbl(ivrs_lookup_ivhd_0x40, ivrs_lookup_ivhd_0x40, ivrs_lookup_ivhd_0x10, &ild); if (!res) { device_printf(dev, "Cannot find IVHD\n"); return (ENXIO); } mtx_init(&sc->iommu.lock, "amdihw", NULL, MTX_DEF); sc->domids = new_unrhdr(0, 0xffff, &sc->iommu.lock); LIST_INIT(&sc->domains); sysctl_ctx_init(&sc->iommu.sysctl_ctx); sc->mmio_sz = ((sc->efr & AMDIOMMU_EFR_PC_SUP) != 0 ? 512 : 16) * 1024; sc->mmio_rid = AMDIOMMU_RID; error = bus_set_resource(dev, SYS_RES_MEMORY, AMDIOMMU_RID, sc->mmio_base, sc->mmio_sz); if (error != 0) { device_printf(dev, "bus_set_resource %#jx-%#jx failed, error %d\n", (uintmax_t)sc->mmio_base, (uintmax_t)sc->mmio_base + sc->mmio_sz, error); error = ENXIO; goto errout1; } sc->mmio_res = bus_alloc_resource(dev, SYS_RES_MEMORY, &sc->mmio_rid, sc->mmio_base, sc->mmio_base + sc->mmio_sz - 1, sc->mmio_sz, RF_ALLOCATED | RF_ACTIVE | RF_SHAREABLE); if (sc->mmio_res == NULL) { device_printf(dev, "bus_alloc_resource %#jx-%#jx failed\n", (uintmax_t)sc->mmio_base, (uintmax_t)sc->mmio_base + sc->mmio_sz); error = ENXIO; goto errout2; } sc->hw_ctrl = amdiommu_read8(sc, AMDIOMMU_CTRL); if (bootverbose) device_printf(dev, "ctrl reg %#jx\n", (uintmax_t)sc->hw_ctrl); if ((sc->hw_ctrl & AMDIOMMU_CTRL_EN) != 0) { device_printf(dev, "CTRL_EN is set, bailing out\n"); error = EBUSY; goto errout2; } iommu_high = BUS_SPACE_MAXADDR; error = amdiommu_create_dev_tbl(sc); if (error != 0) goto errout3; error = amdiommu_init_cmd(sc); if (error != 0) goto errout4; error = amdiommu_init_event(sc); if (error != 0) goto errout5; error = amdiommu_setup_intr(sc); if (error != 0) goto errout6; error = iommu_init_busdma(AMD2IOMMU(sc)); if (error != 0) goto errout7; error = amdiommu_init_irt(sc); if (error != 0) goto errout8; /* * Unlike DMAR, AMD IOMMU does not process command queue * unless IOMMU is enabled. But since non-present devtab * entry makes IOMMU ignore transactions from corresponding * initiator, de-facto IOMMU operations are disabled for the * DMA and intr remapping. */ AMDIOMMU_LOCK(sc); sc->hw_ctrl |= AMDIOMMU_CTRL_EN; amdiommu_write8(sc, AMDIOMMU_CTRL, sc->hw_ctrl); if (bootverbose) { printf("amdiommu%d: enabled translation\n", AMD2IOMMU(sc)->unit); } AMDIOMMU_UNLOCK(sc); TAILQ_INSERT_TAIL(&amdiommu_units, sc, unit_next); return (0); errout8: iommu_fini_busdma(&sc->iommu); errout7: pci_release_msi(dev); errout6: amdiommu_fini_event(sc); errout5: amdiommu_fini_cmd(sc); errout4: amdiommu_free_dev_tbl(sc); errout3: bus_release_resource(dev, SYS_RES_MEMORY, sc->mmio_rid, sc->mmio_res); errout2: bus_delete_resource(dev, SYS_RES_MEMORY, sc->mmio_rid); errout1: sysctl_ctx_free(&sc->iommu.sysctl_ctx); delete_unrhdr(sc->domids); mtx_destroy(&sc->iommu.lock); return (error); } static int amdiommu_detach(device_t dev) { return (EBUSY); } static int amdiommu_suspend(device_t dev) { /* XXXKIB */ return (0); } static int amdiommu_resume(device_t dev) { /* XXXKIB */ return (0); } static device_method_t amdiommu_methods[] = { DEVMETHOD(device_probe, amdiommu_probe), DEVMETHOD(device_attach, amdiommu_attach), DEVMETHOD(device_detach, amdiommu_detach), DEVMETHOD(device_suspend, amdiommu_suspend), DEVMETHOD(device_resume, amdiommu_resume), DEVMETHOD_END }; static driver_t amdiommu_driver = { "amdiommu", amdiommu_methods, sizeof(struct amdiommu_unit), }; EARLY_DRIVER_MODULE(amdiommu, pci, amdiommu_driver, 0, 0, BUS_PASS_SUPPORTDEV); MODULE_DEPEND(amdiommu, pci, 1, 1, 1); static struct amdiommu_unit * amdiommu_unit_by_device_id(u_int pci_seg, u_int device_id) { struct amdiommu_unit *unit; TAILQ_FOREACH(unit, &amdiommu_units, unit_next) { if (unit->unit_dom == pci_seg && unit->device_id == device_id) return (unit); } return (NULL); } struct ivhd_find_unit { u_int domain; uintptr_t rid; int devno; enum { IFU_DEV_PCI, IFU_DEV_IOAPIC, IFU_DEV_HPET, } type; u_int device_id; uint16_t rid_real; uint8_t dte; uint32_t edte; }; static bool amdiommu_find_unit_scan_ivrs(ACPI_IVRS_DE_HEADER *d, size_t tlen, struct ivhd_find_unit *ifu) { char *db, *de; size_t len; for (de = (char *)d + tlen; (char *)d < de; d = (ACPI_IVRS_DE_HEADER *)(db + len)) { db = (char *)d; if (d->Type == ACPI_IVRS_TYPE_PAD4) { len = sizeof(ACPI_IVRS_DEVICE4); } else if (d->Type == ACPI_IVRS_TYPE_ALL) { ACPI_IVRS_DEVICE4 *d4; d4 = (ACPI_IVRS_DEVICE4 *)db; len = sizeof(*d4); ifu->dte = d4->Header.DataSetting; } else if (d->Type == ACPI_IVRS_TYPE_SELECT) { ACPI_IVRS_DEVICE4 *d4; d4 = (ACPI_IVRS_DEVICE4 *)db; if (d4->Header.Id == ifu->rid) { ifu->dte = d4->Header.DataSetting; ifu->rid_real = ifu->rid; return (true); } len = sizeof(*d4); } else if (d->Type == ACPI_IVRS_TYPE_START) { ACPI_IVRS_DEVICE4 *d4, *d4n; d4 = (ACPI_IVRS_DEVICE4 *)db; d4n = d4 + 1; if (d4n->Header.Type != ACPI_IVRS_TYPE_END) { printf("IVRS dev4 start not followed by END " "(%#x)\n", d4n->Header.Type); return (false); } if (d4->Header.Id <= ifu->rid && ifu->rid <= d4n->Header.Id) { ifu->dte = d4->Header.DataSetting; ifu->rid_real = ifu->rid; return (true); } len = 2 * sizeof(*d4); } else if (d->Type == ACPI_IVRS_TYPE_PAD8) { len = sizeof(ACPI_IVRS_DEVICE8A); } else if (d->Type == ACPI_IVRS_TYPE_ALIAS_SELECT) { ACPI_IVRS_DEVICE8A *d8a; d8a = (ACPI_IVRS_DEVICE8A *)db; if (d8a->Header.Id == ifu->rid) { ifu->dte = d8a->Header.DataSetting; ifu->rid_real = d8a->UsedId; return (true); } len = sizeof(*d8a); } else if (d->Type == ACPI_IVRS_TYPE_ALIAS_START) { ACPI_IVRS_DEVICE8A *d8a; ACPI_IVRS_DEVICE4 *d4; d8a = (ACPI_IVRS_DEVICE8A *)db; d4 = (ACPI_IVRS_DEVICE4 *)(d8a + 1); if (d4->Header.Type != ACPI_IVRS_TYPE_END) { printf("IVRS alias start not followed by END " "(%#x)\n", d4->Header.Type); return (false); } if (d8a->Header.Id <= ifu->rid && ifu->rid <= d4->Header.Id) { ifu->dte = d8a->Header.DataSetting; ifu->rid_real = d8a->UsedId; return (true); } len = sizeof(*d8a) + sizeof(*d4); } else if (d->Type == ACPI_IVRS_TYPE_EXT_SELECT) { ACPI_IVRS_DEVICE8B *d8b; d8b = (ACPI_IVRS_DEVICE8B *)db; if (d8b->Header.Id == ifu->rid) { ifu->dte = d8b->Header.DataSetting; ifu->rid_real = ifu->rid; ifu->edte = d8b->ExtendedData; return (true); } len = sizeof(*d8b); } else if (d->Type == ACPI_IVRS_TYPE_EXT_START) { ACPI_IVRS_DEVICE8B *d8b; ACPI_IVRS_DEVICE4 *d4; d8b = (ACPI_IVRS_DEVICE8B *)db; d4 = (ACPI_IVRS_DEVICE4 *)(db + sizeof(*d8b)); if (d4->Header.Type != ACPI_IVRS_TYPE_END) { printf("IVRS ext start not followed by END " "(%#x)\n", d4->Header.Type); return (false); } if (d8b->Header.Id >= ifu->rid && ifu->rid <= d4->Header.Id) { ifu->dte = d8b->Header.DataSetting; ifu->rid_real = ifu->rid; ifu->edte = d8b->ExtendedData; return (true); } len = sizeof(*d8b) + sizeof(*d4); } else if (d->Type == ACPI_IVRS_TYPE_SPECIAL) { ACPI_IVRS_DEVICE8C *d8c; d8c = (ACPI_IVRS_DEVICE8C *)db; if (((ifu->type == IFU_DEV_IOAPIC && d8c->Variety == ACPI_IVHD_IOAPIC) || (ifu->type == IFU_DEV_HPET && d8c->Variety == ACPI_IVHD_HPET)) && ifu->devno == d8c->Handle) { ifu->dte = d8c->Header.DataSetting; ifu->rid_real = d8c->UsedId; return (true); } len = sizeof(*d8c); } else if (d->Type == ACPI_IVRS_TYPE_HID) { ACPI_IVRS_DEVICE_HID *dh; dh = (ACPI_IVRS_DEVICE_HID *)db; len = sizeof(*dh) + dh->UidLength; /* XXXKIB */ } else { #if 0 printf("amdiommu: unknown IVRS device entry type %#x\n", d->Type); #endif if (d->Type <= 63) len = sizeof(ACPI_IVRS_DEVICE4); else if (d->Type <= 127) len = sizeof(ACPI_IVRS_DEVICE8A); else { printf("amdiommu: abort, cannot " "advance iterator, item type %#x\n", d->Type); return (false); } } } return (false); } static bool amdiommu_find_unit_scan_0x11(ACPI_IVRS_HARDWARE2 *ivrs, void *arg) { struct ivhd_find_unit *ifu = arg; ACPI_IVRS_DE_HEADER *d; bool res; KASSERT(ivrs->Header.Type == ACPI_IVRS_TYPE_HARDWARE2 || ivrs->Header.Type == ACPI_IVRS_TYPE_HARDWARE3, ("Misparsed IVHD h2, ivrs type %#x", ivrs->Header.Type)); if (ifu->domain != ivrs->PciSegmentGroup) return (false); d = (ACPI_IVRS_DE_HEADER *)(ivrs + 1); res = amdiommu_find_unit_scan_ivrs(d, ivrs->Header.Length, ifu); if (res) ifu->device_id = ivrs->Header.DeviceId; return (res); } static bool amdiommu_find_unit_scan_0x10(ACPI_IVRS_HARDWARE1 *ivrs, void *arg) { struct ivhd_find_unit *ifu = arg; ACPI_IVRS_DE_HEADER *d; bool res; KASSERT(ivrs->Header.Type == ACPI_IVRS_TYPE_HARDWARE1, ("Misparsed IVHD h1, ivrs type %#x", ivrs->Header.Type)); if (ifu->domain != ivrs->PciSegmentGroup) return (false); d = (ACPI_IVRS_DE_HEADER *)(ivrs + 1); res = amdiommu_find_unit_scan_ivrs(d, ivrs->Header.Length, ifu); if (res) ifu->device_id = ivrs->Header.DeviceId; return (res); } static void amdiommu_dev_prop_dtr(device_t dev, const char *name, void *val, void *dtr_ctx) { free(val, M_DEVBUF); } static int * amdiommu_dev_fetch_flagsp(struct amdiommu_unit *unit, device_t dev) { int *flagsp, error; bus_topo_assert(); error = device_get_prop(dev, device_get_nameunit(unit->iommu.dev), (void **)&flagsp); if (error == ENOENT) { flagsp = malloc(sizeof(int), M_DEVBUF, M_WAITOK | M_ZERO); device_set_prop(dev, device_get_nameunit(unit->iommu.dev), flagsp, amdiommu_dev_prop_dtr, unit); } return (flagsp); } static int amdiommu_get_dev_prop_flags(struct amdiommu_unit *unit, device_t dev) { int *flagsp, flags; bus_topo_lock(); flagsp = amdiommu_dev_fetch_flagsp(unit, dev); flags = *flagsp; bus_topo_unlock(); return (flags); } static void amdiommu_set_dev_prop_flags(struct amdiommu_unit *unit, device_t dev, int flag) { int *flagsp; bus_topo_lock(); flagsp = amdiommu_dev_fetch_flagsp(unit, dev); *flagsp |= flag; bus_topo_unlock(); } int amdiommu_find_unit(device_t dev, struct amdiommu_unit **unitp, uint16_t *ridp, uint8_t *dtep, uint32_t *edtep, bool verbose) { struct ivhd_find_unit ifu; struct amdiommu_unit *unit; int error, flags; bool res; if (!amdiommu_enable) return (ENXIO); if (device_get_devclass(device_get_parent(dev)) != devclass_find("pci")) return (ENXIO); bzero(&ifu, sizeof(ifu)); ifu.type = IFU_DEV_PCI; error = pci_get_id(dev, PCI_ID_RID, &ifu.rid); if (error != 0) { if (verbose) device_printf(dev, "amdiommu cannot get rid, error %d\n", error); return (ENXIO); } ifu.domain = pci_get_domain(dev); res = amdiommu_ivrs_iterate_tbl(amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x10, &ifu); if (!res) { if (verbose) device_printf(dev, "(%#06x:%#06x) amdiommu cannot match rid in IVHD\n", ifu.domain, (unsigned)ifu.rid); return (ENXIO); } unit = amdiommu_unit_by_device_id(ifu.domain, ifu.device_id); if (unit == NULL) { if (verbose) device_printf(dev, "(%#06x:%#06x) amdiommu cannot find unit\n", ifu.domain, (unsigned)ifu.rid); return (ENXIO); } *unitp = unit; iommu_device_set_iommu_prop(dev, unit->iommu.dev); if (ridp != NULL) *ridp = ifu.rid_real; if (dtep != NULL) *dtep = ifu.dte; if (edtep != NULL) *edtep = ifu.edte; if (verbose) { flags = amdiommu_get_dev_prop_flags(unit, dev); if ((flags & AMDIOMMU_DEV_REPORTED) == 0) { amdiommu_set_dev_prop_flags(unit, dev, AMDIOMMU_DEV_REPORTED); device_printf(dev, "amdiommu%d " "initiator rid %#06x dte %#x edte %#x\n", unit->iommu.unit, ifu.rid_real, ifu.dte, ifu.edte); } } return (0); } int amdiommu_find_unit_for_ioapic(int apic_id, struct amdiommu_unit **unitp, uint16_t *ridp, uint8_t *dtep, uint32_t *edtep, bool verbose) { struct ivhd_find_unit ifu; struct amdiommu_unit *unit; device_t apic_dev; bool res; if (!amdiommu_enable) return (ENXIO); bzero(&ifu, sizeof(ifu)); ifu.type = IFU_DEV_IOAPIC; ifu.devno = apic_id; ifu.rid = -1; res = amdiommu_ivrs_iterate_tbl(amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x10, &ifu); if (!res) { if (verbose) printf("amdiommu cannot match ioapic no %d in IVHD\n", apic_id); return (ENXIO); } unit = amdiommu_unit_by_device_id(0, ifu.device_id); apic_dev = ioapic_get_dev(apic_id); if (apic_dev != NULL) iommu_device_set_iommu_prop(apic_dev, unit->iommu.dev); if (unit == NULL) { if (verbose) printf("amdiommu cannot find unit by dev id %#x\n", ifu.device_id); return (ENXIO); } *unitp = unit; if (ridp != NULL) *ridp = ifu.rid_real; if (dtep != NULL) *dtep = ifu.dte; if (edtep != NULL) *edtep = ifu.edte; if (verbose) { printf("amdiommu%d IOAPIC %d " "initiator rid %#06x dte %#x edte %#x\n", unit->iommu.unit, apic_id, ifu.rid_real, ifu.dte, ifu.edte); } return (0); } int amdiommu_find_unit_for_hpet(device_t hpet, struct amdiommu_unit **unitp, uint16_t *ridp, uint8_t *dtep, uint32_t *edtep, bool verbose) { struct ivhd_find_unit ifu; struct amdiommu_unit *unit; int hpet_no; bool res; if (!amdiommu_enable) return (ENXIO); hpet_no = hpet_get_uid(hpet); bzero(&ifu, sizeof(ifu)); ifu.type = IFU_DEV_HPET; ifu.devno = hpet_no; ifu.rid = -1; res = amdiommu_ivrs_iterate_tbl(amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x11, amdiommu_find_unit_scan_0x10, &ifu); if (!res) { if (verbose) printf("amdiommu cannot match hpet no %d in IVHD\n", hpet_no); return (ENXIO); } unit = amdiommu_unit_by_device_id(0, ifu.device_id); if (unit == NULL) { if (verbose) printf("amdiommu cannot find unit id %d\n", hpet_no); return (ENXIO); } *unitp = unit; iommu_device_set_iommu_prop(hpet, unit->iommu.dev); if (ridp != NULL) *ridp = ifu.rid_real; if (dtep != NULL) *dtep = ifu.dte; if (edtep != NULL) *edtep = ifu.edte; if (verbose) { printf("amdiommu%d HPET no %d " "initiator rid %#06x dte %#x edte %#x\n", unit->iommu.unit, hpet_no, ifu.rid_real, ifu.dte, ifu.edte); } return (0); } static struct iommu_unit * amdiommu_find_method(device_t dev, bool verbose) { struct amdiommu_unit *unit; int error; uint32_t edte; uint16_t rid; uint8_t dte; error = amdiommu_find_unit(dev, &unit, &rid, &dte, &edte, verbose); if (error != 0) { if (verbose && amdiommu_enable) device_printf(dev, "cannot find amdiommu unit, error %d\n", error); return (NULL); } return (&unit->iommu); } static struct x86_unit_common * amdiommu_get_x86_common(struct iommu_unit *unit) { struct amdiommu_unit *iommu; iommu = IOMMU2AMD(unit); return (&iommu->x86c); } static void amdiommu_unit_pre_instantiate_ctx(struct iommu_unit *unit) { } static struct x86_iommu amd_x86_iommu = { .get_x86_common = amdiommu_get_x86_common, .unit_pre_instantiate_ctx = amdiommu_unit_pre_instantiate_ctx, .find = amdiommu_find_method, .domain_unload_entry = amdiommu_domain_unload_entry, .domain_unload = amdiommu_domain_unload, .get_ctx = amdiommu_get_ctx, .free_ctx_locked = amdiommu_free_ctx_locked_method, .alloc_msi_intr = amdiommu_alloc_msi_intr, .map_msi_intr = amdiommu_map_msi_intr, .unmap_msi_intr = amdiommu_unmap_msi_intr, .map_ioapic_intr = amdiommu_map_ioapic_intr, .unmap_ioapic_intr = amdiommu_unmap_ioapic_intr, }; static void x86_iommu_set_amd(void *arg __unused) { if (cpu_vendor_id == CPU_VENDOR_AMD) set_x86_iommu(&amd_x86_iommu); } SYSINIT(x86_iommu, SI_SUB_TUNABLES, SI_ORDER_ANY, x86_iommu_set_amd, NULL); #ifdef DDB #include #include static void amdiommu_print_domain(struct amdiommu_domain *domain, bool show_mappings) { struct iommu_domain *iodom; iodom = DOM2IODOM(domain); db_printf( " @%p dom %d pglvl %d end %jx refs %d\n" " ctx_cnt %d flags %x pgobj %p map_ents %u\n", domain, domain->domain, domain->pglvl, (uintmax_t)domain->iodom.end, domain->refs, domain->ctx_cnt, domain->iodom.flags, domain->pgtbl_obj, domain->iodom.entries_cnt); iommu_db_domain_print_contexts(iodom); if (show_mappings) iommu_db_domain_print_mappings(iodom); } static void amdiommu_print_one(struct amdiommu_unit *unit, bool show_domains, bool show_mappings, bool show_cmdq) { struct amdiommu_domain *domain; struct amdiommu_cmd_generic *cp; u_int cmd_head, cmd_tail, ci; cmd_head = amdiommu_read4(unit, AMDIOMMU_CMDBUF_HEAD); cmd_tail = amdiommu_read4(unit, AMDIOMMU_CMDBUF_TAIL); db_printf("amdiommu%d at %p, mmio at %#jx/sz %#jx\n", unit->iommu.unit, unit, (uintmax_t)unit->mmio_base, (uintmax_t)unit->mmio_sz); db_printf(" hw ctrl %#018jx cmdevst %#018jx\n", (uintmax_t)amdiommu_read8(unit, AMDIOMMU_CTRL), (uintmax_t)amdiommu_read8(unit, AMDIOMMU_CMDEV_STATUS)); db_printf(" devtbl at %p\n", unit->dev_tbl); db_printf(" hwseq at %p phys %#jx val %#jx\n", &unit->x86c.inv_waitd_seq_hw, pmap_kextract((vm_offset_t)&unit->x86c.inv_waitd_seq_hw), unit->x86c.inv_waitd_seq_hw); db_printf(" invq at %p base %#jx hw head/tail %#x/%#x\n", unit->x86c.inv_queue, (uintmax_t)amdiommu_read8(unit, AMDIOMMU_CMDBUF_BASE), cmd_head, cmd_tail); if (show_cmdq) { db_printf(" cmd q:\n"); for (ci = cmd_head; ci != cmd_tail;) { cp = (struct amdiommu_cmd_generic *)(unit-> x86c.inv_queue + ci); db_printf( " idx %#x op %#x %#010x %#010x %#010x %#010x\n", ci >> AMDIOMMU_CMD_SZ_SHIFT, cp->op, cp->w0, cp->ww1, cp->w2, cp->w3); ci += AMDIOMMU_CMD_SZ; if (ci == unit->x86c.inv_queue_size) ci = 0; } } if (show_domains) { db_printf(" domains:\n"); LIST_FOREACH(domain, &unit->domains, link) { amdiommu_print_domain(domain, show_mappings); if (db_pager_quit) break; } } } DB_SHOW_COMMAND(amdiommu, db_amdiommu_print) { struct amdiommu_unit *unit; bool show_domains, show_mappings, show_cmdq; show_domains = strchr(modif, 'd') != NULL; show_mappings = strchr(modif, 'm') != NULL; show_cmdq = strchr(modif, 'q') != NULL; if (!have_addr) { db_printf("usage: show amdiommu [/d] [/m] [/q] index\n"); return; } if ((vm_offset_t)addr < 0x10000) unit = amdiommu_unit_by_device_id(0, (u_int)addr); else unit = (struct amdiommu_unit *)addr; amdiommu_print_one(unit, show_domains, show_mappings, show_cmdq); } DB_SHOW_ALL_COMMAND(amdiommus, db_show_all_amdiommus) { struct amdiommu_unit *unit; bool show_domains, show_mappings, show_cmdq; show_domains = strchr(modif, 'd') != NULL; show_mappings = strchr(modif, 'm') != NULL; show_cmdq = strchr(modif, 'q') != NULL; TAILQ_FOREACH(unit, &amdiommu_units, unit_next) { amdiommu_print_one(unit, show_domains, show_mappings, show_cmdq); if (db_pager_quit) break; } } #endif